INTEL 864075-ND

PRELIMINARY
8XC196NU COMMERCIAL
CHMOS 16-BIT MICROCONTROLLER
■ 50 MHz Operation†
■ 1 Mbyte of Linear Address Space
■ Optional 48 Kbytes of ROM
■ 1 Kbyte of Register RAM
■ Register-register Architecture
■ Footprint and Functionally Compatible
Upgrade for the 8XC196NP
■ 32 I/O Port Pins
■ 16 Prioritized Interrupt Sources
■ 4 External Interrupt Pins and NMI Pin
■ 2 Flexible 16-bit Timer/Counters with
Quadrature Counting Capability
■ 3 Pulse-width Modulator (PWM)
Outputs with High Drive Capability
■ Full-duplex Serial Port with Dedicated
Baud-rate Generator
■ Peripheral Transaction Server
†
40 MHz standard; 50 MHz is Speed Premium
■ Chip-select Unit
— 6 Chip-select Pins
— Dynamic Demultiplexed/Multiplexed
Address/Data Bus for Each
Chip Select
— Programmable Wait States
(0–3) for Each Chip Select
— Programmable Bus Width
(8- or 16-bit) for Each Chip Select
— Programmable Address Range for
Each Chip Select
■ Event Processor Array (EPA) with
4 High-speed Capture/Compare
Channels
■ Multiply and Accumulate Executes in
640 ns Using the 32-bit Hardware
Accumulator
■ 960 ns 32/16 Unsigned Division
■ 100-pin SQFP or 100-pin QFP Package
■ Complete System Development
Support
■ High-speed CHMOS Technology
The 8XC196NU is a member of Intel’s 16-bit MCS® 96 microcontroller family. The device features 1 Mbyte of
linear address space, a demultiplexed bus, and a chip-select unit. The external bus can dynamically switch
between multiplexed and demultiplexed operation.
COPYRIGHT © INTEL CORPORATION, 1997
February 1997
Order Number: 272644-004
Information in this document is provided in connection with Intel products. No license, express or implied, by estoppel or otherwise, to any intellectual property rights is granted by this document. Except as provided in Intel’s
Terms and Conditions of Sale for such products, Intel assumes no liability whatsoever, and Intel disclaims any
express or implied warranty, relating to sale and/or use of Intel products including liability or warranties relating to
fitness for a particular purpose, merchantability, or infringement of any patent, copyright or other intellectual property right. Intel products are not intended for use in medical, life saving, or life sustaining applications.
Intel retains the right to make changes to specifications and product descriptions at any time, without notice.
*Third-party brands and names are the property of their respective owners.
Copies of documents which have an ordering number and are referenced in this document, or other Intel literature,
may be obtained from:
Intel Corporation
P.O. Box 7641
Mt. Prospect, IL 60056-7641
or call 1-800-548-4725
CONTENTS
8XC196NU Commercial
CHMOS 16-bit Microcontroller
1.0 Product Overview ................................................................................................................ 1
2.0 Nomenclature Overview ...................................................................................................... 2
3.0 Pinout .................................................................................................................................. 3
4.0 Signals .............................................................................................................................. 12
5.0 Address Map ..................................................................................................................... 19
6.0 Electrical Characteristics ................................................................................................... 20
6.1 DC Characteristics........................................................................................................ 21
6.2 AC Characteristics........................................................................................................ 23
6.2.1 Relationship of XTAL1 to CLKOUT .......................................................................23
6.2.2 Explanation of AC Symbols ...................................................................................24
6.2.3 AC Characteristics — Multiplexed Bus Mode ........................................................25
6.2.4 AC Characteristics — Demultiplexed Bus Mode ...................................................29
6.2.5 HOLD#, HLDA# Timings .......................................................................................34
6.2.6 AC Characteristics — Serial Port, Synchronous Mode 0 ......................................35
6.2.7 External Clock Drive ..............................................................................................36
7.0 Thermal Characteristics .................................................................................................... 38
8.0 8XC196NU Errata ............................................................................................................ 38
9.0 Datasheet Revision History ............................................................................................... 38
Figures
1.
8XC196NU Block Diagram...................................................................................................1
2.
The 8XC196NU Family Nomenclature .................................................................................2
3.
80C196NU 100-pin SQFP Package.....................................................................................3
4.
80C196NU 100-pin QFP Package .......................................................................................6
5.
83C196NU 100-pin QFP Package .......................................................................................9
6.
Effect of Clock Mode on CLKOUT......................................................................................23
7.
System Bus Timings, Multiplexed Bus Mode .....................................................................27
8.
READY Timing, Multiplexed Bus Mode..............................................................................28
9.
System Bus Timings, Demultiplexed Bus Mode.................................................................31
10. READY Timing, Demultiplexed Bus Mode .........................................................................32
11. Deferred Bus Mode Timing Diagram..................................................................................33
12. HOLD#, HLDA# Timing Diagram .......................................................................................34
13. Serial Port Waveform — Synchronous Mode 0..................................................................35
14. External Clock Drive Waveforms........................................................................................36
15. AC Testing Output Waveforms During 5.0 Volt Testing .....................................................36
16. Float Waveforms During 5.0 Volt Testing...........................................................................37
iii
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
Tables
1.
Description of Product Nomenclature...................................................................................2
2.
80C196NU 100-pin SQFP Pin Assignment..........................................................................4
3.
80C196NU 100-pin SQFP Pin Assignment Arranged by Functional Categories .................5
4.
80C196NU 100-pin QFP Pin Assignment ............................................................................7
5.
80C196NU 100-pin QFP Pin Assignment Arranged by Functional Categories....................8
6.
83C196NU 100-pin QFP Pin Assignment ..........................................................................10
7.
83C196NU 100-pin QFP Pin Assignment Arranged by Functional Categories..................11
8.
Signal Descriptions ............................................................................................................12
9.
8XC196NU Address Map ...................................................................................................19
10. DC Characteristics Over Specified Operating Conditions ..................................................21
11. AC Timing Symbol Definitions............................................................................................24
12. AC Characteristics the 8XC196NU Will Meet, Multiplexed Bus Mode ...............................25
13. AC Characteristics the External Memory System Must Meet, Multiplexed Bus Mode .......26
14. AC Characteristics the 8XC196NU Will Meet, Demultiplexed Bus Mode...........................29
15. AC Characteristics the External Memory System Must Meet, Demultiplexed Bus Mode...30
16. HOLD#, HLDA# Timings ....................................................................................................34
17. Serial Port Timing — Synchronous Mode 0 .......................................................................35
18. External Clock Drive...........................................................................................................36
19. Thermal Characteristics .....................................................................................................38
iv
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
1.0
PRODUCT OVERVIEW
The 8XC196NU is a member of Intel’s 16-bit MCS® 96 microcontroller family. The device features 1 Mbyte of
linear address space, a demultiplexed bus, and a chip-select unit. The external bus can dynamically switch
between multiplexed and demultiplexed operation.
16
CPU
1000
Byte
Register
File
24 Bytes
CPU SFRs
RALU
48 Kbytes
ROM
(optional)
Interrupt
Controller
Peripheral
Transaction
Server
Microcode
Engine
Memory Controller
with
Chip Select
Chip Select
CS5:0#
Control
Signals
Queue
8
A19:16/
EPORT3:0
16
A15:0
Timer 1
Timer 2
Event
Processor
Array
Serial
Port
Port 1
Port 2
Port 1/
EPA3:0,
Timer 1,
Timer 2
Port 2/
Hold Control,
SIO,
EXTINT1:0
Pulse
Width
Modulator
Baud
Rate
Gen
Port
3
AD15:0
Port
4
Port 3/
Port 4/
EXTINT3:2 PWM2:0
A2822-02
Figure 1. 8XC196NU Block Diagram
PRELIMINARY
1
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
2.0
NOMENCLATURE OVERVIEW
X
XX
8
X
X
XXXXX
XX
ag
i ng
atu
er
n
tio
s
dB
an
Op
re
in
n-
ur
ns
tio
Op
ed
pe
eS
vic
De
ily
am
tF
uc
od
on
Pr
ati
ns
rm
tio
nfo
Op
sI
ry
es
mo
oc
Pr
me
mra
og
Pr
ck
mp
Pa
Te
A2815-01
Figure 2. The 8XC196NU Family Nomenclature
Table 1. Description of Product Nomenclature
Parameter
Temperature and Burn-in Options
Packaging Options
Program–memory Options
Process Information
Product Family
Device Speed
2
Options
Description
no mark
Commercial operating temperature range (0°C to 70°C)
with Intel standard burn-in.
S
SB
QFP
SQFP
0
Without ROM
3
ROM
C
CHMOS
196NU
—
no mark
40 MHz
50
50 MHz
PRELIMINARY
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
PINOUT
100
99
98
97
96
95
94
93
92
91
90
89
88
87
86
85
84
83
82
81
80
79
78
77
76
AD0
AD1
AD2
AD3
AD4
AD5
AD6
AD7
VCC
AD8
VSS
AD9
AD10
AD11
AD12
AD13
AD14
AD15
A16 / EPORT.0
A17 / EPORT.1
VCC
VSS
A18 / EPORT.2
A19 / EPORT.3
WR# / WRL#
3.0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
SB80C196NU
View of component as
mounted on PC board
75
74
73
72
71
70
69
68
67
66
65
64
63
62
61
60
59
58
57
56
55
54
53
52
51
RD#
BHE# / WRH#
ALE
INST
READY
RPD
ONCE
PLLEN2
VCC
VSS
A8
A9
A10
A11
A12
A13
A14
A15
NC
VSS
XTAL1
XTAL2
VSS
VCC
P2.7 / CLKOUT
P3.7 / EXTINT3
P1.0 / EPA0
VCC
P1.1 / EPA1
P1.2 / EPA2
P1.3 / EPA3
P1.4 / T1CLK
P1.5 / T1DIR
VCC
P1.6 / T2CLK
VSS
P1.7 / T2DIR
P4.0 / PWM0
P4.1 / PWM1
P4.2 / PWM2
P4.3
VCC
VSS
P2.0 / TXD
P2.1 / RXD
P2.2 / EXTINT0
P2.3 / BREQ#
P2.4 / EXTINT1
P2.5 / HOLD#
P2.6 / HLDA#
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
RESET#
NMI
NC
A0
A1
VCC
VSS
A2
A3
A4
A5
A6
A7
VCC
VSS
NC
PLLEN1
P3.0 / CS0#
P3.1 / CS1#
P3.2 / CS2#
P3.3 / CS3#
VSS
P3.4 / CS4#
P3.5 / CS5#
P3.6 / EXTINT2
A2823-03
Figure 3. 80C196NU 100-pin SQFP Package
PRELIMINARY
3
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
Table 2. 80C196NU 100-pin SQFP Pin Assignment
Pin
Name
Name
Pin
Name
Pin
Name
1
RESET#
26
EXTINT3/P3.7
51
CLKOUT/P2.7
76
WR#/WRL#
2
NMI
27
EPA0/P1.0
52
VCC
77
EPORT.3/A19
3
NC
28
VCC
53
VSS
78
EPORT.2/A18
4
A0
29
EPA1/P1.1
54
XTAL2
79
VSS
5
A1
30
EPA2/P1.2
55
XTAL1
80
VCC
6
VCC
31
EPA3/P1.3
56
VSS
81
EPORT.1/A17
7
VSS
32
T1CLK/P1.4
57
NC
82
EPORT.0/A16
8
A2
33
T1DIR/P1.5
58
A15
83
AD15
9
A3
34
VCC
59
A14
84
AD14
10
A4
35
T2CLK/P1.6
60
A13
85
AD13
11
A5
36
VSS
61
A12
86
AD12
12
A6
37
T2DIR/P1.7
62
A11
87
AD11
13
A7
38
PWM0/P4.0
63
A10
88
AD10
14
VCC
39
PWM1/P4.1
64
A9
89
AD9
15
VSS
40
PWM2/P4.2
65
A8
90
VSS
16
NC
41
P4.3
66
VSS
91
AD8
17
PLLEN1
42
VCC
67
VCC
92
VCC
18
CS0#/P3.0
43
VSS
68
PLLEN2
93
AD7
19
CS1#/P3.1
44
TXD/P2.0
69
ONCE
94
AD6
20
CS2#/P3.2
45
RXD/P2.1
70
RPD
95
AD5
21
CS3#/P3.3
46
EXTINT0/P2.2
71
READY
96
AD4
22
VSS
47
BREQ#/P2.3
72
INST
97
AD3
23
CS4#/P3.4
48
EXTINT1/P2.4
73
ALE
98
AD2
24
CS5#/P3.5
49
HOLD#/P2.5
74
BHE#/WRH#
99
AD1
25
EXTINT2/P3.6
50
HLDA#/P2.6
75
RD#
100
AD0
NOTE:
4
Pin
To be compatible with future products, tie the NC (no connection) pins as follows: Pin 57 = VSS,
Pin 16 = VCC, and Pin 3 = NC.
PRELIMINARY
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
Table 3. 80C196NU 100-pin SQFP Pin Assignment Arranged by Functional Categories
Address & Data
(continued)
Address & Data
Name
Pin
Name
Input/Output
Power & Ground
Pin
Name
Pin
A0
4
AD12
86
CS0#/P3.0
18
VCC
6
A1
5
AD13
85
CS1#/P3.1
19
VCC
14
A2
8
AD14
84
CS2#/P3.2
20
VCC
28
A3
9
AD15
83
A4
10
A5
11
A6
12
Bus Control & Status
Name
Name
Pin
CS3#/P3.3
21
VCC
34
CS4#/P3.4
23
VCC
42
CS5#/P3.5
24
VCC
52
Pin
EPA0/P1.0
27
VCC
67
A7
13
ALE
73
EPA1/P1.1
29
VCC
80
A8
65
BHE#/WRH#
74
EPA2/P1.2
30
VCC
92
A9
64
BREQ#
47
EPA3/P1.3
31
VSS
7
A10
63
HOLD#
49
EPORT.0
82
VSS
15
A11
62
HLDA#
50
EPORT.1
81
VSS
22
A12
61
INST
72
EPORT.2
78
VSS
36
A13
60
RD#
75
EPORT.3
77
VSS
43
A14
59
READY
71
P2.2
46
VSS
53
A15
58
WR#/WRL#
76
P2.3
47
VSS
56
A16
82
P2.4
48
VSS
66
A17
81
P2.5
49
VSS
79
A18
78
P2.6
50
VSS
90
Processor Control
Name
Pin
A19
77
CLKOUT
51
P2.7
51
AD0
100
EXTINT0
46
P3.6
25
AD1
99
EXTINT1
48
P3.7
26
AD2
98
EXTINT2
25
P4.3
41
No Connection
Name
NC
Pin
3
AD3
97
EXTINT3
26
PWM0/P4.0
38
NC
16
AD4
96
NMI
2
PWM1/P4.1
39
NC
57
AD5
95
ONCE
69
PWM2/P4.2
40
AD6
94
RESET#
1
RXD/P2.1
45
AD7
93
RPD
70
T1CLK/P1.4
32
AD8
91
XTAL1
55
T1DIR/P1.5
33
AD9
89
XTAL2
54
T2CLK/P1.6
35
AD10
88
PLLEN1
17
T2DIR/P1.7
37
AD11
87
PLLEN2
68
TXD/P2.0
44
PRELIMINARY
5
100
99
98
97
96
95
94
93
92
91
90
89
88
87
86
85
84
83
82
81
AD1
AD2
AD3
AD4
AD5
AD6
AD7
VCC
AD8
VSS
AD9
AD10
AD11
AD12
AD13
AD14
AD15
A16 / EPORT.0
A17 / EPORT.1
VCC
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
S80C196NU
View of component as
mounted on PC board
80
79
78
77
76
75
74
73
72
71
70
69
68
67
66
65
64
63
62
61
60
59
58
57
56
55
54
53
52
51
VSS
A18 / EPORT.2
A19 / EPORT.3
WR# / WRL#
RD#
BHE# / WRH#
ALE
INST
READY
RPD
ONCE
PLLEN2
VCC
VSS
A8
A9
A10
A11
A12
A13
A14
A15
VSS
XTAL1
XTAL2
VSS
P2.7 / CLKOUT
VCC
P2.6 / HLDA#
P2.5 / HOLD#
P1.1 / EPA1
P1.2 / EPA2
P1.3 / EPA3
P1.4 / T1CLK
P1.5 / T1DIR
VCC
P1.6 / T2CLK
VSS
P1.7 / T2DIR
P4.0 / PWM0
P4.1 / PWM1
P4.2 / PWM2
P4.3
VCC
VSS
P2.0 / TXD
P2.1 / RXD
P2.2 / EXTINT0
P2.3 / BREQ#
P2.4 / EXTINT1
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
AD0
NC
RESET#
NMI
NC
A0
A1
VCC
VSS
A2
A3
A4
A5
A6
A7
VCC
VSS
PLLEN1
P3.0 / CS0#
P3.1 / CS1#
P3.2 / CS2#
P3.3 / CS3#
VSS
P3.4 / CS4#
P3.5 / CS5#
P3.6 / EXTINT2
NC
P3.7 / EXTINT3
P1.0 / EPA0
VCC
A2824-03
Figure 4. 80C196NU 100-pin QFP Package
6
PRELIMINARY
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
Table 4. 80C196NU 100-pin QFP Pin Assignment
Pin
Name
Pin
Name
Pin
Name
Pin
Name
1
AD0
26
EXTINT2/P3.6
51
HOLD#/P2.5
76
RD#
2
NC
27
NC
52
HLDA#/P2.6
77
WR#/WRL#
3
RESET#
28
EXTINT3/P3.7
53
VCC
78
EPORT.3/A19
4
NMI
29
EPA0/P1.0
54
CLKOUT/P2.7
79
EPORT.2/A18
5
NC
30
VCC
55
VSS
80
VSS
6
A0
31
EPA1/P1.1
56
XTAL2
81
VCC
7
A1
32
EPA2/P1.2
57
XTAL1
82
EPORT.1/A17
8
VCC
33
EPA3/P1.3
58
VSS
83
EPORT.0/A16
9
VSS
34
T1CLK/P1.4
59
A15
84
AD15
10
A2
35
T1DIR/P1.5
60
A14
85
AD14
11
A3
36
VCC
61
A13
86
AD13
12
A4
37
T2CLK/P1.6
62
A12
87
AD12
13
A5
38
VSS
63
A11
88
AD11
14
A6
39
T2DIR/P1.7
64
A10
89
AD10
15
A7
40
PWM0/P4.0
65
A9
90
AD9
16
VCC
41
PWM1/P4.1
66
A8
91
VSS
17
VSS
42
PWM2/P4.2
67
VSS
92
AD8
18
PLLEN1
43
P4.3
68
VCC
93
VCC
19
CS0#/P3.0
44
VCC
69
PLLEN2
94
AD7
20
CS1#/P3.1
45
VSS
70
ONCE
95
AD6
21
CS2#/P3.2
46
TXD/P2.0
71
RPD
96
AD5
22
CS3#/P3.3
47
RXD/P2.1
72
READY
97
AD4
23
VSS
48
EXTINT0/P2.2
73
INST
98
AD3
24
CS4#/P3.4
49
BREQ#/P2.3
74
ALE
99
AD2
25
CS5#/P3.5
50
EXTINT1/P2.4
75
BHE#/WRH#
100
AD1
NOTE:
To be compatible with future proliferations, tie the NC (no connect) pin as follows:
Pin 2 = VSS
Pin 5 = EA# on products with internal memory (VCC = internal memory, VSS = external memory)
Pin 27 = VCC
PRELIMINARY
7
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
Table 5. 80C196NU 100-pin QFP Pin Assignment Arranged by Functional Categories
Address & Data
(continued)
Address & Data
Name
8
Name
Power & Ground
Pin
Name
Pin
6
AD12
87
CS0#/P3.0
19
VCC
8
A1
7
AD13
86
CS1#/P3.1
20
VCC
16
A2
10
AD14
85
CS2#/P3.2
21
VCC
30
A3
11
AD15
84
A4
12
A5
13
A6
14
A7
15
ALE
74
A8
66
BHE#/WRH#
75
A9
65
BREQ#
49
EPA3/P1.3
33
VSS
9
A10
64
HOLD#
51
EPORT.0
83
VSS
17
A11
63
HLDA#
52
EPORT.1
82
VSS
23
A12
62
INST
73
EPORT.2
79
VSS
38
A0
Pin
Input/Output
Bus Control & Status
Name
Pin
Name
Pin
CS3#/P3.3
22
VCC
36
CS4#/P3.4
24
VCC
44
CS5#/P3.5
25
VCC
53
EPA0/P1.0
29
VCC
68
EPA1/P1.1
31
VCC
81
EPA2/P1.2
32
VCC
93
A13
61
RD#
76
EPORT.3
78
VSS
45
A14
60
READY
72
P2.2
48
VSS
55
A15
59
WR#/WRL#
77
P2.3
49
VSS
58
A16
83
P2.4
50
VSS
67
A17
82
P2.5
51
VSS
80
A18
79
P2.6
52
VSS
91
A19
78
CLKOUT
54
P2.7
54
AD0
1
EXTINT0
48
P3.6
26
AD1
100
EXTINT1
50
P3.7
28
AD2
99
EXTINT2
26
P4.3
43
NC
Processor Control
Name
Pin
No Connection
Name
Pin
2
AD3
98
EXTINT3
28
PWM0/P4.0
40
NC
5
AD4
97
NMI
4
PWM1/P4.1
41
NC
27
AD5
96
ONCE
70
PWM2/P4.2
42
AD6
95
RESET#
3
RXD/P2.1
47
AD7
94
RPD
71
T1CLK/P1.4
34
AD8
92
XTAL1
57
T1DIR/P1.5
35
AD9
90
XTAL2
56
T2CLK/P1.6
37
AD10
89
PLLEN1
18
T2DIR/P1.7
39
AD11
88
PLLEN2
69
TXD/P2.0
46
PRELIMINARY
100
99
98
97
96
95
94
93
92
91
90
89
88
87
86
85
84
83
82
81
AD1
AD2
AD3
AD4
AD5
AD6
AD7
VCC
AD8
VSS
AD9
AD10
AD11
AD12
AD13
AD14
AD15
A16 / EPORT.0
A17 / EPORT.1
VCC
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
S83C196NU
View of component as
mounted on PC board
80
79
78
77
76
75
74
73
72
71
70
69
68
67
66
65
64
63
62
61
60
59
58
57
56
55
54
53
52
51
VSS
A18 / EPORT.2
A19 / EPORT.3
WR# / WRL#
RD#
BHE# / WRH#
ALE
INST
READY
RPD
ONCE
PLLEN2
VCC
VSS
A8
A9
A10
A11
A12
A13
A14
A15
VSS
XTAL1
XTAL2
VSS
P2.7 / CLKOUT
VCC
P2.6 / HLDA#
P2.5 / HOLD#
P1.1 / EPA1
P1.2 / EPA2
P1.3 / EPA3
P1.4 / T1CLK
P1.5 / T1DIR
VCC
P1.6 / T2CLK
VSS
P1.7 / T2DIR
P4.0 / PWM0
P4.1 / PWM1
P4.2 / PWM2
P4.3
VCC
VSS
P2.0 / TXD
P2.1 / RXD
P2.2 / EXTINT0
P2.3 / BREQ#
P2.4 / EXTINT1
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
AD0
NC
RESET#
NMI
EA#
A0
A1
VCC
VSS
A2
A3
A4
A5
A6
A7
VCC
VSS
PLLEN1
P3.0 / CS0#
P3.1 / CS1#
P3.2 / CS2#
P3.3 / CS3#
VSS
P3.4 / CS4#
P3.5 / CS5#
P3.6 / EXTINT2
NC
P3.7 / EXTINT3
P1.0 / EPA0
VCC
A3217-02
Figure 5. 83C196NU 100-pin QFP Package
PRELIMINARY
9
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
Table 6. 83C196NU 100-pin QFP Pin Assignment
Pin
Name
Pin
Name
Pin
Name
Pin
Name
1
AD0
26
EXTINT2/P3.6
51
HOLD#/P2.5
76
RD#
2
NC
27
NC
52
HLDA#/P2.6
77
WR#/WRL#
3
RESET#
28
EXTINT3/P3.7
53
VCC
78
EPORT.3/A19
4
NMI
29
EPA0/P1.0
54
CLKOUT/P2.7
79
EPORT.2/A18
5
EA#
30
VCC
55
VSS
80
VSS
6
A0
31
EPA1/P1.1
56
XTAL2
81
VCC
7
A1
32
EPA2/P1.2
57
XTAL1
82
EPORT.1/A17
8
VCC
33
EPA3/P1.3
58
VSS
83
EPORT.0/A16
9
VSS
34
T1CLK/P1.4
59
A15
84
AD15
10
A2
35
T1DIR/P1.5
60
A14
85
AD14
11
A3
36
VCC
61
A13
86
AD13
12
A4
37
T2CLK/P1.6
62
A12
87
AD12
13
A5
38
VSS
63
A11
88
AD11
14
A6
39
T2DIR/P1.7
64
A10
89
AD10
15
A7
40
PWM0/P4.0
65
A9
90
AD9
16
VCC
41
PWM1/P4.1
66
A8
91
VSS
17
VSS
42
PWM2/P4.2
67
VSS
92
AD8
18
PLLEN1
43
P4.3
68
VCC
93
VCC
19
CS0#/P3.0
44
VCC
69
PLLEN2
94
AD7
20
CS1#/P3.1
45
VSS
70
ONCE
95
AD6
21
CS2#/P3.2
46
TXD/P2.0
71
RPD
96
AD5
22
CS3#/P3.3
47
RXD/P2.1
72
READY
97
AD4
23
VSS
48
EXTINT0/P2.2
73
INST
98
AD3
24
CS4#/P3.4
49
BREQ#/P2.3
74
ALE
99
AD2
25
CS5#/P3.5
50
EXTINT1/P2.4
75
BHE#/WRH#
100
AD1
NOTE:
To be compatible with future proliferations, tie the NC (no connect) pins as follows:
Pin 2 = VSS
Pin 27 = VCC.
10
PRELIMINARY
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
Table 7. 83C196NU 100-pin QFP Pin Assignment Arranged by Functional Categories
Address & Data
(continued)
Address & Data
Name
Name
Power & Ground
Pin
Name
Pin
6
AD12
87
CS0#/P3.0
19
A1
7
AD13
86
CS1#/P3.1
A2
10
AD14
85
CS2#/P3.2
A3
11
AD15
84
CS3#/P3.3
A4
12
Bus Control & Status
CS4#/P3.4
A5
13
A6
14
A7
15
BHE#/WRH#
75
EPA1/P1.1
A8
66
BREQ#
49
EPA2/P1.2
A9
65
HOLD#
51
EPA3/P1.3
33
VSS
9
A10
64
HLDA#
52
EPORT.0
83
VSS
17
A11
63
INST
73
EPORT.1
82
VSS
23
A12
62
RD#
76
EPORT.2
79
VSS
38
A13
61
READY
72
EPORT.3
78
VSS
45
A14
60
WR#/WRL#
77
P2.2
48
VSS
55
A15
59
A16
83
A17
82
A18
79
A19
AD0
A0
Pin
Input/Output
Name
ALE
Name
Pin
VCC
8
20
VCC
16
21
VCC
30
22
VCC
36
24
VCC
44
Pin
CS5#/P3.5
25
VCC
53
74
EPA0/P1.0
29
VCC
68
31
VCC
81
32
VCC
93
Processor Control
P2.3
49
VSS
58
P2.4
50
VSS
67
Pin
P2.5
51
VSS
80
CLKOUT
54
P2.6
52
VSS
91
78
EXTINT0
48
P2.7
54
1
EXTINT1
50
P3.6
26
AD1
100
EXTINT2
26
P3.7
28
AD2
99
EXTINT3
28
P4.3
43
NC
2
AD3
98
NMI
4
PWM0/P4.0
40
NC
27
AD4
97
ONCE
70
PWM1/P4.1
41
AD5
96
RESET#
3
PWM2/P4.2
42
AD6
95
RPD
71
RXD/P2.1
47
AD7
94
XTAL1
57
T1CLK/P1.4
34
AD8
92
XTAL2
56
T1DIR/P1.5
35
AD9
90
PLLEN1
18
T2CLK/P1.6
37
AD10
89
PLLEN2
69
T2DIR/P1.7
39
AD11
88
EA#
5
TXD/P2.0
46
PRELIMINARY
Name
No Connection
Name
Pin
11
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
4.0
SIGNALS
Table 8. Signal Descriptions
Name
Type
Description
A15:0
I/O
System Address Bus
These address lines provide address bits 0–15 during the entire external memory cycle during both multiplexed and demultiplexed bus modes.
A19:16
I/O
Address Lines 16–19
These address lines provide address bits 16–19 during the entire external
memory cycle, supporting extended addressing of the 1 Mbyte address space.
NOTE: Internally, there are 24 address bits; however, only 20 external
address pins (A19:0) are implemented. The internal address space is
16 Mbytes (000000–FFFFFFH) and the external address space is
1 Mbyte (00000–FFFFFH). The device resets to FF2080H in internal
memory or F2080H in external memory.
AD15:0
I/O
Address/Data Lines
The functions of these pins depend on the bus size and mode. When a bus
access is not occurring, these pins revert to their I/O port function.
16-bit Multiplexed Bus Mode:
AD15:0 drive address bits 0–15 during the first half of the bus cycle and drive or
receive data during the second half of the bus cycle.
8-bit Multiplexed Bus Mode:
AD15:8 drive address bits 8–15 during the entire bus cycle. AD7:0 drive
address bits 0–7 during the first half of the bus cycle and drive or receive data
during the second half of the bus cycle.
16-bit Demultiplexed Mode:
AD15:0 drive or receive data during the entire bus cycle.
8-bit Demultiplexed Mode:
AD7:0 drive or receive data during the entire bus cycle. AD15:8 drive the data
that is currently on the high byte of the internal bus.
ALE
O
Address Latch Enable
This active-high output signal is asserted only during external memory cycles.
ALE signals the start of an external bus cycle and indicates that valid address
information is available on the system address/data bus (A19:16 and AD15:0 for
a multiplexed bus; A19:0 for a demultiplexed bus). ALE differs from ADV# in that
it does not remain active during the entire bus cycle.
An external latch can use this signal to demultiplex the address bits 0–15 from
the address/data bus in multiplexed mode.
A19:16 are multiplexed with EPORT.3:0.
12
PRELIMINARY
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
Table 8. Signal Descriptions (Continued)
Name
BHE#
Type
O
Description
Byte High Enable
†
During 16-bit bus cycles, this active-low output signal is asserted for word reads
and writes and high-byte reads and writes to external memory. BHE# indicates
that valid data is being transferred over the upper half of the system data bus.
Use BHE#, in conjunction with A0, to determine which memory byte is being
transferred over the system bus:
BHE#
A0
Byte(s) Accessed
0
0
both bytes
0
1
high byte only
1
0
low byte only
BHE# is multiplexed with WRH#.
†
The chip configuration register 0 (CCR0) determines whether this pin functions as BHE# or WRH#. CCR0.2 = 1 selects BHE#; CCR0.2 = 0 selects
WRH#.
BREQ#
O
Bus Request
This active-low output signal is asserted during a hold cycle when the bus controller has a pending external memory cycle. When the bus-hold protocol is
enabled (WSR.7 is set), the P2.3/BREQ# pin can function only as BREQ#,
regardless of the configuration selected through the port configuration registers
(P2_MODE, P2_DIR, and P2_REG). An attempt to change the pin configuration
is ignored until the bus-hold protocol is disabled (WSR.7 is cleared).
BREQ# is multiplexed with P2.3.
CLKOUT
O
Clock Output
Output of the internal clock generator. The CLKOUT frequency is ½ the internal
operating frequency (f). CLKOUT has a 50% duty cycle.
CLKOUT is multiplexed with P2.7.
CS5#:0
O
Chip-select Lines 0–5
The active-low output CSx# is asserted during an external memory cycle when
the address to be accessed is in the range programmed for chip select x. If the
external memory address is outside the range assigned to the six chip selects,
no chip-select output is asserted and the bus configuration defaults to the CS5#
values.
Immediately following reset, CS0# is automatically assigned to the range
FF2000–FF20FFH (F2000–F20FFH if external).
CS5:0# is multiplexed with P3.5:0.
EA#
I
External Access
This active-low input signal determines whether memory accesses to special
purpose and program memory partitions (FF2000–FFDFFFH) are directed to
internal or external memory. These memory accesses are directed to internal
memory if EA# is deasserted and to external memory if EA# is asserted. For an
access to any other memory location, the value of EA# is irrelevant.
EA# is not latched and can be switched dynamically during normal operating
mode. Be sure to thoroughly consider the issues, such as different access times
for internal and external memory, before using this dynamic switching capability.
Always connect EA# to VSS when using a microcontroller that has no internal
nonvolatile memory.
PRELIMINARY
13
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
Table 8. Signal Descriptions (Continued)
Name
Type
Description
EPA3:0
I/O
Event Processor Array (EPA) Input/Output pins
These are the high-speed input/output pins for the EPA capture/compare channels. For high-speed PWM applications, the outputs of two EPA channels (either
EPA0 and EPA1 or EPA2 and EPA3) can be remapped to produce a PWM waveform on a shared output pin.
EPA3:0 are multiplexed with P1.3:0.
EPORT.3:0
I/O
Extended Addressing Port
This is a standard, 4-bit, bidirectional I/O port.
EPORT.3:0 are multiplexed with A19:16.
EXTINT3:0
I
External Interrupts
In normal operating mode, a rising edge on EXTINTx sets the EXTINTx interrupt pending bit. EXTINTx is sampled during phase 2 (CLKOUT high). The minimum high time is one state time.
In standby and powerdown modes, asserting the EXTINTx signal for at least 50
ns causes the device to resume normal operation. The interrupt need not be
enabled, but the pin must be configured as a special-function input. If the
EXTINTx interrupt is enabled, the CPU executes the interrupt service routine.
Otherwise, the CPU executes the instruction that immediately follows the command that invoked the power-saving mode.
In idle mode, asserting any enabled interrupt causes the device to resume normal operation.
EXTINT0 is multiplexed with P2.2, EXTINT1 is multiplexed with P2.4, EXTINT2
is multiplexed with P3.6, and EXTINT3 is multiplexed with P3.7.
HLDA#
O
Bus Hold Acknowledge
This active-low output indicates that the CPU has released the bus as the result
of an external device asserting HOLD#. When the bus-hold protocol is enabled
(WSR.7 is set), the P2.6/HLDA# pin can function only as HLDA#, regardless of
the configuration selected through the port configuration registers (P2_MODE,
P2_DIR, and P2_REG). An attempt to change the pin configuration is ignored
until the bus-hold protocol is disabled (WSR.7 is cleared).
HLDA# is multiplexed with P2.6.
HOLD#
I
Bus Hold Request
An external device uses this active-low input signal to request control of the bus.
When the bus-hold protocol is enabled (WSR.7 is set), the P2.5/HOLD# pin can
function only as HOLD#, regardless of the configuration selected through the
port configuration registers (P2_MODE, P2_DIR, and P2_REG). An attempt to
change the pin configuration is ignored until the bus-hold protocol is disabled
(WSR.7 is cleared).
HOLD# is multiplexed with P2.5.
INST
O
Instruction Fetch
This active-high output signal is valid only during external memory bus cycles.
When high, INST indicates that an instruction is being fetched from external
memory. The signal remains high during the entire bus cycle of an external
instruction fetch. INST is low for data accesses, including interrupt vector
fetches and chip configuration byte reads. INST is low during internal memory
fetches.
14
PRELIMINARY
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
Table 8. Signal Descriptions (Continued)
Name
Type
Description
NMI
I
Nonmaskable Interrupt
In normal operating mode, a rising edge on NMI generates a nonmaskable
interrupt. NMI has the highest priority of all prioritized interrupts. Assert NMI for
greater than one state time to guarantee that it is recognized.
ONCE
I
On-circuit Emulation
Holding ONCE high during the rising edge of RESET# places the device into
on-circuit emulation (ONCE) mode. This mode puts all pins into a high-impedance state, thereby isolating the device from other components in the system.
The value of ONCE is latched when the RESET# pin goes inactive. While the
device is in ONCE mode, you can debug the system using a clip-on emulator.
To exit ONCE mode, reset the device by pulling the RESET# signal low. To prevent accidental entry into ONCE mode, connect the ONCE pin to VSS.
P1.7:0
I/O
Port 1
This is a standard bidirectional port that is multiplexed with individually selectable special-function signals.
Port 1 is multiplexed as follows: P1.0/EPA0, P1.1/EPA1, P1.2/EPA2, P1.3/EPA3,
P1.4/T1CLK, P1.5/T1DIR, P1.6/T2CLK, and P1.7/T2DIR.
P2.7:0
I/O
Port 2
This is a standard bidirectional port that is multiplexed with individually selectable special-function signals.
Port 2 is multiplexed as follows: P2.0/TXD, P2.1/RXD, P2.2/EXTINT0, P2.3/
BREQ#, P2.4/EXTINT1, P2.5/HOLD#, P2.6/HLDA#, and P2.7/CLKOUT.
P3.7:0
I/O
Port 3
This is an 8-bit, bidirectional, standard I/O port.
Port 3 is multiplexed as follows: P3.0/CS0#, P3.1/CS1#, P3.2/CS2#, P3.3/
CS3#, P3.4/CS4#, P3.5/CS5#, P3.6/EXTINT2, and P3.7/EXTINT3.
P4.3:0
I/O
Port 4
This is a 4-bit, bidirectional, standard I/O port with high-current drive capability.
Port 4 is multiplexed as follows: P4.0/PWM0, P4.1/PWM1, and P4.2/PWM2.
P4.3 is not multiplexed.
PLLEN2:1
I
Phase-locked Loop 1 and 2 Enable
These input pins are used to enable the on-chip clock multiplier feature and
select either the doubled or quadrupled clock speed as follows:
PLLEN2
PLLEN1
Mode
†
PRELIMINARY
0
0
1
0
0
1
1
1
Standard mode; clock multiplier circuitry disabled.
Internal clock equals the XTAL1 input frequency.
Reserved†
Doubled mode; clock multiplier circuitry enabled.
Internal clock is twice the XTAL1 input frequency.
Quadrupled mode; clock multiplier circuitry enabled.
Internal clock is four times the XTAL1 input
frequency.
This reserved combination causes the device to enter an unsupported test
mode.
15
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
Table 8. Signal Descriptions (Continued)
Name
Type
Description
PWM2:0
O
Pulse Width Modulator Outputs
These are PWM output pins with high-current drive capability. The duty cycle
and frequency-pulse-widths are programmable.
PWM2:0 are multiplexed with P4.2:0.
RD#
O
Read
Read-signal output to external memory. RD# is asserted only during external
memory reads.
READY
I
Ready Input
This active-high input signal is used to lengthen external memory cycles for
slow memory by generating wait states in addition to the wait states that are
generated internally.
When READY is high, CPU operation continues in a normal manner with wait
states inserted as programmed in the chip configuration registers or the chipselect x bus control register. READY is ignored for all internal memory
accesses.
RESET#
I/O
RPD
I
Reset
A level-sensitive reset input to and open-drain system reset output from the
microcontroller. Either a falling edge on RESET# or an internal reset turns on a
pull-down transistor connected to the RESET# pin for 16 state times. In the
powerdown, standby, and idle modes, asserting RESET# causes the chip to
reset and return to normal operating mode. If the phase-locked loop (PLL) clock
circuitry is enabled, you must hold RESET# low for at least 2 ms to allow the
PLL to stabilize before the internal CPU and peripheral clocks are enabled.
After a device reset, the first instruction fetch is from FF2080H (or F2080H in
external memory). The program and special-purpose memory locations
(FF2000–FF2FFFH) reside in external memory.
Return from Powerdown
Timing pin for the return-from-powerdown circuit.
If your application uses powerdown mode, connect a capacitor between RPD
and VSS if either of the following conditions is true:
• the internal oscillator is the clock source
• the phase-locked loop (PLL) circuitry is enabled (see PLLEN2:1 signal
description)
The capacitor causes a delay that enables the oscillator and PLL circuitry to
stabilize before the internal CPU and peripheral clocks are enabled.
The capacitor is not required if your application uses powerdown mode and if
both of the following conditions are true:
• an external clock input is the clock source
• the phase-locked loop circuitry is disabled
If your application does not use powerdown mode, leave this pin unconnected.
RXD
16
I/O
Receive Serial Data
In modes 1, 2, and 3, RXD receives serial port input data. In mode 0, it functions as either an input or an open-drain output for data.
RXD is multiplexed with P2.1.
PRELIMINARY
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
Table 8. Signal Descriptions (Continued)
Name
Type
Description
T1CLK
I
Timer 1 External Clock
External clock for timer 1. Timer 1 increments (or decrements) on both rising
and falling edges of T1CLK. Also used in conjunction with T1DIR for quadrature
counting mode.
and
External clock for the serial I/O baud-rate generator input (program selectable).
T1CLK is multiplexed with P1.4.
T2CLK
I
Timer 2 External Clock
External clock for timer 2. Timer 2 increments (or decrements) on both rising
and falling edges of T2CLK. Also used in conjunction with T2DIR for quadrature
counting mode.
T2CLK is multiplexed with P1.6.
T1DIR
I
Timer 1 External Direction
External direction (up/down) for timer 1. Timer 1 increments when T1DIR is high
and decrements when it is low. Also used in conjunction with T1CLK for quadrature counting mode.
T1DIR is multiplexed with P1.5.
T2DIR
I
Timer 2 External Direction
External direction (up/down) for timer 2. Timer 2 increments when T2DIR is high
and decrements when it is low. Also used in conjunction with T2CLK for quadrature counting mode.
T2DIR is multiplexed with P1.7.
TXD
O
Transmit Serial Data
In serial I/O modes 1, 2, and 3, TXD transmits serial port output data. In mode
0, it is the serial clock output.
TXD is multiplexed with P2.0.
VCC
PWR
Digital Supply Voltage
Connect each VCC pin to the digital supply voltage.
VSS
GND
Digital Circuit Ground
Connect each VSS pin to ground through the lowest possible impedance path.
WR#
O
Write†
This active-low output indicates that an external write is occurring. This signal is
asserted only during external memory writes.
WR# is multiplexed with WRL#.
†
The chip configuration register 0 (CCR0) determines whether this pin functions as WR# or WRL#. CCR0.2 = 1 selects WR#; CCR0.2 = 0 selects WRL#.
WRH#
O
Write High†
During 16-bit bus cycles, this active-low output signal is asserted for high-byte
writes and word writes to external memory. During 8-bit bus cycles, WRH# is
asserted for all write operations.
WRH# is multiplexed with BHE#.
†
The chip configuration register 0 (CCR0) determines whether this pin functions as BHE# or WRH#. CCR0.2 = 1 selects BHE#; CCR0.2 = 0 selects
WRH#.
PRELIMINARY
17
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
Table 8. Signal Descriptions (Continued)
Name
Type
Description
†
WRL#
O
Write Low
During 16-bit bus cycles, this active-low output signal is asserted for low-byte
writes and word writes. During 8-bit bus cycles, WRL# is asserted for all write
operations.
WRL# is multiplexed with WR#.
† The chip configuration register 0 (CCR0) determines whether this pin functions as WR# or WRL#. CCR0.2 = 1 selects WR#; CCR0.2 = 0 selects WRL#.
XTAL1
I
Input Crystal/Resonator or External Clock Input
Input to the on-chip oscillator, phase-locked loop circuitry, and the internal clock
generators. The internal clock generators provide the peripheral clocks, CPU
clock, and CLKOUT signal. When using an external clock source instead of the
on-chip oscillator, connect the clock input to XTAL1. The external clock signal
must meet the VIH specification for XTAL1 (see datasheet).
XTAL2
O
Inverted Output for the Crystal/Resonator
Output of the on-chip oscillator inverter. Leave XTAL2 floating when the design
uses a external clock source instead of the on-chip oscillator.
18
PRELIMINARY
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
5.0
ADDRESS MAP
Table 9. 8XC196NU Address Map
Hex
Address
Description
Addressing Modes
FF FFFFH
FF E000H
External device (memory or I/O) connected to address/data bus
Indirect, indexed, extended
FF DFFFH
Program memory (Note 1)
FF 2080H
Indirect, indexed, extended
FF 207FH
FF 2000H
Special-purpose memory (Note 1)
Indirect, indexed, extended
FF 1FFFH
FF 0100H
External device (memory or I/O) connected to address/data bus
Indirect, indexed, extended
FF 00FFH
FF 0000H
Reserved for ICE (Note 2)
FE FFFFH
0F 0000H
Overlaid memory (reserved for future devices) (Note 2)
Indirect, indexed, extended
0E FFFFH
01 0000H
External device (memory or I/O) connected to address/data bus
Indirect, indexed, extended
00 FFFFH
00 E000H
External device (memory or I/O) connected to address/data bus
Indirect, indexed, extended
00 DFFFH
00 2000H
External device (memory or I/O) connected to address/data bus
or remapped internal ROM (determined by EA# pin) (Note 3)
Indirect, indexed, extended
00 1FFFH
00 1F00H
Internal peripheral special-function registers (SFRs) (Note 4)
Indirect, indexed,
extended, windowed direct
00 1EFFH
00 0400H
External device (memory or I/O) connected to address/data bus
Indirect, indexed, extended
00 03FFH
00 0100H
Upper register file (general-purpose register RAM)
Indirect, indexed,
windowed direct
00 00FFH
00 001AH
Lower register file (general-purpose register RAM)
Direct, indirect, indexed,
windowed direct
00 0019H
00 0018H
Lower register file (stack pointer)
Direct, indirect, indexed,
windowed direct
00 0017H
00 0000H
Lower register file (CPU SFRs) (Note 4)
Direct, indirect, indexed,
windowed direct
—
NOTES:
1. For the 80C196NU, the program and special-purpose memory locations (FF2000–FFDFFFH) reside
in external memory. For the 83C196NU, these locations can reside either in external memory or in
internal ROM.
2. Locations xF0000–xF00FFH are reserved, write 0FFH to these locations.
3. For the 80C196NU, this address range (FF2080–FFDFFFH) is always external memory. For the
83C196NU, this address range is mapped into internal ROM if the REMAP bit (CCB1.2) is set and
EA# is at logic 1. Otherwise, they are mapped to external memory.
4. Unless otherwise noted, write 0 to reserved SFR bits.
PRELIMINARY
19
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
6.0
ELECTRICAL CHARACTERISTICS
ABSOLUTE MAXIMUM RATINGS*
Storage Temperature ................................... –60°C to +150°C
Supply Voltage with Respect to VSS............... –0.5 V to +7.0 V
Power Dissipation ........................................................... 1.5 W
NOTICE: This document contains information on
products in the sampling and initial production
phases of development. The specifications are
subject to change without notice. Verify with your
local Intel sales office that you have the latest
datasheet before finalizing a design.
OPERATING CONDITIONS*
TA (Ambient Temperature Under Bias) ................ 0°C to +70°C
VCC (Digital Supply Voltage) ............................. 4.5 V to 5.5 V
FXTAL1 (Input frequency for VCC = 4.5 V – 5.5 V)
(Note 1, 2, 3)........................................ 16 MHz to 50 MHz
NOTES:
1. This device is static and should operate below
1 Hz, but has been tested only down to 16 MHz.
2. The maximum crystal that can be used is 25 MHz.
3. The minimum XTAL1 frequency when using the
PLL is 8 MHz.
20
*WARNING: Stressing the device beyond the
“Absolute Maximum Ratings” may cause
permanent damage. These are stress ratings only.
Operation beyond the “Operating Conditions” is not
recommended and extended exposure beyond the
“Operating Conditions” may affect device reliability.
PRELIMINARY
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
6.1
DC Characteristics
Table 10. DC Characteristics Over Specified Operating Conditions
Symbol
Parameter
Min
Typical
(Note 1)
Max
Units
Test
Conditions
ICC
VCC Supply Current
90
120
mA
XTAL1 = 50 MHz
VCC = 5.5 V
Device in Reset
IIDLE
Idle Mode Current
45
60
mA
XTAL1 = 50 MHz
VCC = 5.5 V
IPD
Powerdown Mode Current
20
50
µA
VCC = 5.5 V
(Note 2)
ISTDBY
Standby Mode
8
15
mA
VCC = 5.5 V
ILI
Input Leakage Current
(Standard Inputs)
±10
µA
VSS < VIN < VCC
VIL
Input Low Voltage (all pins)
–0.5
0.8
V
VIH
Input High Voltage
0.2 VCC + 1
VCC + 0.5
V
VIL1
Input Low Voltage XTAL1
–0.5
0.3 VCC
V
VIH1
Input High Voltage XTAL1
0.7 VCC
VCC + 0.5
V
VIH2
Input High Voltage (Reset
pin) (Note 3)
0.2 VCC + 1.4
VCC + 0.5
V
VOL
Output Low Voltage (output
configured as complementary) (Note 4, 5)
0.3
0.45
1.5
V
V
V
IOL = 200 µA
IOL = 3.2 mA
IOL = 7.0 mA
VOH
Output High Voltage (output
configured as complementary) (Note 5)
V
V
V
IOH = –200 µA
IOH = –3.2 mA
IOH = –7.0 mA
VCC – 0.3
VCC – 0.7
VCC – 1.5
NOTES:
1. Typical values are based on a limited number of samples and are not guaranteed. The values listed
are at room temperature with VCC = 5.0 V.
2. For temperatures below 100°C, typical is 10 µA.
3. B-step only.
4. For all pins except P4.3:0, which have higher drive capability (see VOL1).
5. During normal (non-transient) conditions, the following maximum current limits apply for pin groups
and individual pins:
6.
7.
Group
IOL (mA)
P1.7:3, P4
P2
P1.2:0, P3
40
40
40
IOH (mA)
40
40
40
Individual
P1, P2, P3
P4
IOL (mA)
10
18
IOH (mA)
10
10
For all pins that were weakly pulled high during RESET. This excludes ALE, INST, and NMI, which
were weakly pulled low (see VOL2) and ONCE, which was pulled medium low (see VOL3).
Pin capacitance is not tested. This value is based on design simulations.
PRELIMINARY
21
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
Table 10. DC Characteristics Over Specified Operating Conditions (Continued)
Symbol
Parameter
Typical
(Note 1)
Min
Max
Units
Test
Conditions
VOL1
Output Low Voltage on P4.x
(output configured as complementary) (Note 5)
0.45
0.6
V
V
IOL = 10 mA
IOL = 15 mA
VOL2
Output Low Voltage in
RESET on ALE, INST, and
NMI
0.45
V
IOL = 3 µA
VOH1
Output High Voltage in
RESET (Note 6)
V
IOH = –3 µA
VOL3
Output Low Voltage in
RESET for ONCE pin
0.45
V
IOL = 30 µA
VOL4
Output Low Voltage on
XTAL2
0.3
0.45
1.5
V
V
V
IOL = 100 µA
IOL = 700 µA
IOL = 3 mA
VOH2
Output High Voltage on
XTAL2
V
V
V
IOH = –100 µA
IOH = –700 µA
IOH = –3 mA
VTH+ –
VTH–
Hysteresis voltage width
on RESET# pin
CS
Pin Capacitance (any pin to
VSS) (Note 7)
RRST
RESET Pull-up Resistor
VCC – 0.7
VCC – 0.3
VCC – 0.7
VCC – 1.5
0.3
9
V
10
pF
95
kΩ
VCC = 5.5 V,
VIN = 4.0 V
NOTES:
1. Typical values are based on a limited number of samples and are not guaranteed. The values listed
are at room temperature with VCC = 5.0 V.
2. For temperatures below 100°C, typical is 10 µA.
3. B-step only.
4. For all pins except P4.3:0, which have higher drive capability (see VOL1).
5. During normal (non-transient) conditions, the following maximum current limits apply for pin groups
and individual pins:
6.
7.
22
Group
IOL (mA)
P1.7:3, P4
P2
P1.2:0, P3
40
40
40
IOH (mA)
40
40
40
Individual
P1, P2, P3
P4
IOL (mA)
10
18
IOH (mA)
10
10
For all pins that were weakly pulled high during RESET. This excludes ALE, INST, and NMI, which
were weakly pulled low (see VOL2) and ONCE, which was pulled medium low (see VOL3).
Pin capacitance is not tested. This value is based on design simulations.
PRELIMINARY
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
6.2
AC Characteristics
6.2.1
RELATIONSHIP OF XTAL1 TO CLKOUT
TXHCH
XTAL1
(12.5 MHz)
f
PLLEN2:1=00
t = 80ns
CLKOUT
f
PLLEN2:1=01
t = 40ns
CLKOUT
f
PLLEN2:1=11
t = 20ns
CLKOUT
A3160-02
Figure 6. Effect of Clock Mode on CLKOUT
PRELIMINARY
23
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
6.2.2
EXPLANATION OF AC SYMBOLS
Each AC timing symbol is two pairs of letters prefixed by “T” for time. The characters in a pair indicate a signal
and its condition, respectively. Symbols represent the time between the two signal/condition points.
Table 11. AC Timing Symbol Definitions
Character
Signal(s)
A
AD15:0, A19:0
B
BHE#
C
CLKOUT
D
AD15:0, AD7:0
H
HOLD#
HA
HLDA#
L
ALE
Q
AD15:0, AD7:0
R
RD#
S
CSx#
W
WR#, WRL#
X
XTAL1,
Y
READY
Character
24
Condition
H
High
L
Low
V
Valid
X
No Longer Valid
Z
Floating (low impedance)
PRELIMINARY
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
6.2.3
AC CHARACTERISTICS — MULTIPLEXED BUS MODE
Test Conditions: Capacitive load on all pins = 50 pF, Rise and Fall Times = 3 ns.
Table 12. AC Characteristics the 8XC196NU Will Meet, Multiplexed Bus Mode
Symbol
FXTAL1
Parameter
Min
Max
Units
Frequency on XTAL1, PLL in 1x mode
16
50 (1)
MHz
Frequency on XTAL1, PLL in 2x mode
8 (2)
25
MHz
Frequency on XTAL1, PLL in 4x mode
8 (2)
12.5
MHz
16
50
MHz
20
62.5
ns
3
50
ns
Operating frequency, f = FXTAL1; PLL in 1x mode
f
Operating frequency, f = 2FXTAL1; PLL in 2x mode
Operating frequency, f = 4FXTAL1; PLL in 4x mode
t
Period, t = 1/f
TXHCH
XTAL1 Rising Edge to CLKOUT High or Low
TCLCL
CLKOUT Cycle Time
TCHCL
CLKOUT High Period
t – 10
TAVWL
Address Valid to WR# Falling Edge
2t – 25
TCLLH
CLKOUT Falling Edge to ALE Rising Edge
TLLCH
ALE Falling Edge to CLKOUT Rising Edge
TLHLH
ALE Cycle Time
4t
TLHLL
ALE High Period
t – 10
TAVLL
Address Valid to ALE Falling Edge
t – 14
ns
TLLAX
Address Hold after ALE Falling Edge
t – 10
ns
TLLRL
ALE Falling Edge to RD# Falling Edge
t – 15
ns
TRLCL
RD# Low to CLKOUT Falling Edge
– 10
TRLRH
RD# Low Period
t – 10
TRHLH
RD# Rising Edge to ALE Rising Edge
t–5
TRLAZ
RD# Low to Address Float
TLLWL
ALE Falling Edge to WR# Falling Edge
t – 11
ns
TQVWH
Data Stable to WR# Rising Edge
t – 14
ns (3)
TCHWH
CLKOUT High to WR# Rising Edge
– 15
2t
ns
t + 15
ns
– 10
10
ns
– 15
15
ns
ns
ns (3)
t + 10
20
ns
ns
ns (3)
t + 15
ns (4)
5
ns
5
ns
NOTES:
1. 25 MHz is the maximum input frequency when using an external crystal oscillator; however, 50 MHz
can be applied with an external clock source.
2. When the phase-locked loop (PLL) circuitry is enabled, the minimum input frequency on XTAL1 is 8
MHz. The PLL cannot be run at frequencies lower than 16 MHz.
3. If wait states are used, add 2t × n, where n = number of wait states.
4. Assuming back-to-back bus cycles.
5. 8-bit bus only.
PRELIMINARY
25
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
Table 12. AC Characteristics the 8XC196NU Will Meet, Multiplexed Bus Mode (Continued)
Symbol
Parameter
Min
Max
Units
TWLWH
WR# Low Period
t – 10
ns (3)
TWHQX
Data Hold after WR# Rising Edge
t–7
ns
TWHLH
WR# Rising Edge to ALE Rising Edge
t – 14
TWHBX
BHE#, INST Hold after WR# Rising Edge
A-step
B-step
t–4
0
ns
TWHAX
AD15:8 Hold after WR# Rising Edge
t–4
ns (5)
TRHBX
BHE#, INST Hold after RD# Rising Edge
A-step
B-step
t
0
ns
t + 20
ns
TRHAX
AD15:8 Hold after RD# Rising Edge
t
ns (5)
TWHSH
A19:16, CS# Hold after WR# Rising Edge
0
ns
TRHSH
A19:16, CS# Hold after RD# Rising Edge
0
ns
NOTES:
1. 25 MHz is the maximum input frequency when using an external crystal oscillator; however, 50 MHz
can be applied with an external clock source.
2. When the phase-locked loop (PLL) circuitry is enabled, the minimum input frequency on XTAL1 is 8
MHz. The PLL cannot be run at frequencies lower than 16 MHz.
3. If wait states are used, add 2t × n, where n = number of wait states.
4. Assuming back-to-back bus cycles.
5. 8-bit bus only.
Table 13. AC Characteristics the External Memory System Must Meet, Multiplexed Bus Mode
Symbol
Parameter
Max
Units
3t – 32
ns (1)
RD# Active to Input Data Valid
t – 22
ns (1)
Chip Select Low to Data Valid
4t – 32
ns (1)
TCHDV
CLKOUT High to Input Data Valid
2t – 25
ns
TRHDZ
End of RD# to Input Data Float
t–5
ns
TRXDX
Data Hold after RD# Inactive
TAVYV
AD15:0 Valid to READY Setup
2t – 38
ns (2)
TCLYX
READY Hold after CLKOUT Low
2t – 36
ns (3)
TYLYH
Non-READY Time
TAVDV
AD15:0 Valid to Input Data Valid
TRLDV
TSLDV
Min
0
0
ns
No Upper Limit
ns
NOTES:
1. If wait states are used, add 2t × n, where n = number of wait states.
2. When forcing wait states using the BUSCON register, add 2t × n.
3. Exceeding the maximum specification causes additional wait states.
26
PRELIMINARY
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
6.2.3.1
System Bus Timings, Multiplexed Bus
TCLCL
TCHDV
t
TCLLH
TRLCL
TCHCL
CLKOUT
TLLCH
TRHLH
TLHLH
TLHLL
TLLRL
ALE
TRLRH
TRLAZ
TRHDZ
RD#
TRLDV
TLLAX
TAVDV
TAVLL
AD15:0
(read)
Address Out
Data In
TCHWH
TWHLH
TWHQX
TLLWL
TWLWH
WR#
TQVWH
AD15:0
(write)
Address Out
Address Out
Data Out
TWHBX, TRHBX
† BHE#, INST
Valid
†† BHE#, INST
Valid
TWHAX, TRHAX
AD15:8
High Address Out
TWHSH, TRHSH
A19:16
Extended Address Out
CSx#
Valid
† 80C196NU A-1 Step
†† 80C196NU B Step and 83C196NU
A4389-01
Figure 7. System Bus Timings, Multiplexed Bus Mode
PRELIMINARY
27
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
6.2.3.2
READY Timing, Multiplexed Bus
TCLYX (max)
CLKOUT
TAVYV
TCLYX (min)
READY
TLHLH + 2t
ALE
TRLRH + 2t
RD#
TRLDV + 2t
TAVDV + 2t
AD15:0
(read)
Data In
TWLWH + 2t
WR#
TQVWH + 2t
AD15:0
(write)
Data Out
† BHE#, INST
Valid
†† BHE#, INST
Valid
A19:0
Extended Address Out
CSx#
Valid
† 80C196NU A-1 Step
†† 80C196NU B Step and 83C196NU
A4388-01
Figure 8. READY Timing, Multiplexed Bus Mode
28
PRELIMINARY
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
6.2.4
AC CHARACTERISTICS — DEMULTIPLEXED BUS MODE
Test Conditions: Capacitive load on all pins = 50 pF, Rise and Fall Times = 3 ns.
Table 14. AC Characteristics the 8XC196NU Will Meet, Demultiplexed Bus Mode
Symbol
FXTAL1
Parameter
Min
Max
Units
Frequency on XTAL1, PLL in 1x mode
16
50 (1)
MHz
Frequency on XTAL1, PLL in 2x mode
8 (2)
25
MHz
Frequency on XTAL1, PLL in 4x mode
8 (2)
12.5
MHz
16
50
MHz
20
62.5
Operating frequency, f = FXTAL1; PLL in 1x mode
f
Operating frequency, f = 2FXTAL1; PLL in 2x mode
Operating frequency, f = 4FXTAL1; PLL in 4x mode
t
Period, t = 1/f
TAVWL
Address Valid to WR# Falling Edge
TAVRL
Address Valid to RD# Falling Edge
t–8
ns(3)
TRHRL
Read High to Next Read Low
t–5
ns(3)
TXHCH
XTAL1 High to CLKOUT High or Low
TCLCL
CLKOUT Cycle Time
TCHCL
CLKOUT High Period
t – 10
t + 15
ns
TCLLH
CLKOUT Falling Edge to ALE Rising Edge
– 10
10
ns
TLLCH
ALE Falling Edge to CLKOUT Rising Edge
– 15
15
TLHLH
ALE Cycle Time
4t
TLHLL
ALE High Period
t – 10
t + 10
ns
TRLCL
RD# Low to CLKOUT Falling Edge
–5
11
ns
TRLRH
RD# Low Period
TRHLH
RD# Rising Edge to ALE Rising Edge
TWLCL
WR# Low to CLKOUT Falling Edge
TQVWH
Data Stable to WR# Rising Edge
TCHWH
CLKOUT High to WR# Rising Edge
TWLWH
WR# Low Period
TWHQX
Data Hold after WR# Rising Edge
t–8
3
50
2t
ns
ns (3,4,5)
ns (4)
t–4
t + 15
–8
5
3t – 25
ns (3)
ns
ns (4)
10
3t – 18
t
ns
ns
3t – 18
– 11
ns
ns(3)
ns
ns (4)
t + 20
ns
NOTES:
1. 25 MHz is the maximum input frequency when using an external crystal oscillator; however, 50 MHz
can be applied with an external clock source.
2. When the phase-locked loop (PLL) circuitry is enabled, the minimum input frequency on XTAL1 is 8
MHz. The PLL cannot be run at frequencies lower than 16 MHz.
3. For deferred bus cycle, add 2t (1 state) if CSx# changes or if the write cycle follows a read cycle.
4. If wait states are used, add 2t × n, where n = number of wait states.
5. Assuming back-to-back bus cycles.
PRELIMINARY
29
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
Table 14. AC Characteristics the 8XC196NU Will Meet, Demultiplexed Bus Mode (Continued)
Symbol
Parameter
Min
Max
Units
t + 10
ns (3)
TWHLH
WR# Rising Edge to ALE Rising Edge
t–5
TWHBX
BHE#, INST Hold after WR# Rising Edge
A-step
B-step
t–5
0
ns
TWHAX
A19:0, CSx# Hold after WR# Rising Edge
0
ns
TRHBX
BHE#, INST Hold after RD# Rising Edge
A-step
B-step
t–5
0
ns
A19:0, CSx# Hold after RD# Rising Edge
0
ns
TRHAX
NOTES:
1. 25 MHz is the maximum input frequency when using an external crystal oscillator; however, 50 MHz
can be applied with an external clock source.
2. When the phase-locked loop (PLL) circuitry is enabled, the minimum input frequency on XTAL1 is 8
MHz. The PLL cannot be run at frequencies lower than 16 MHz.
3. For deferred bus cycle, add 2t (1 state) if CSx# changes or if the write cycle follows a read cycle.
4. If wait states are used, add 2t × n, where n = number of wait states.
5. Assuming back-to-back bus cycles.
Table 15. AC Characteristics the External Memory System Must Meet, Demultiplexed Bus Mode
Symbol
Parameter
Min
Max
Units
TAVDV
A19:0 Valid to Input Data Valid
4t – 25
ns (1,2)
TRLDV
RD# Active to Input Data Valid
3t – 35
ns (1)
TSLDV
Chip Select Low to Data Valid
4t – 25
ns (1,2)
TCHDV
CLKOUT High to Input Data Valid
2t – 25
ns
TRHDZ
End of RD# to Input Data Float
TRXDX
Data Hold after RD# Inactive
TAVYV
A19:0 Valid to READY Setup
TCLYX
READY Hold after CLKOUT Low
TYLYH
Non READY Time
t
0
0
ns
ns
3t – 45
ns (3)
2t – 26
ns (4)
No Upper Limit
ns
NOTES:
1. If wait states are used, add 2t × n, where n = number of wait states.
2. For deferred bus cycle, add 2t (1 state) if CSx# changes or if the write cycle follows a read cycle.
3. When forcing wait states using the BUSCON register, add 2t × n.
4. Exceeding the maximum specification causes additional wait states.
30
PRELIMINARY
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
6.2.4.1
System Bus Timings, Demultiplexed Bus
TCLCL
TCHCL
TCLLH
t
TCHWH
CLKOUT
TLHLH
TWHLH
TRHLH
TLLCH
TLHLL
ALE
TAVRL
TRHRL
TRHDZ
TRHAX
TRLRH
RD#
TCHDV
TRLDV
TAVDV
TSLDV
AD15:0
(read)
Data In
TWLCL
TWHQX
TWHAX
TAVWL
TWLWH
WR#
TQVWH
AD15:0
(write)
Data Out
Valid
† BHE#, INST
TWHBX,TRHBX
†† BHE#, INST
Valid
A19:0
Address Out
CSx#
Valid
† 80C196NU A-1 Step
†† 80C196NU B Step and 83C196NU
A4390-01
Figure 9. System Bus Timings, Demultiplexed Bus Mode
PRELIMINARY
31
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
6.2.4.2
READY Timing, Demultiplexed Bus
TCLYX (max)
CLKOUT
TAVYV
TCLYX (min)
READY
TLHLH + 2t
ALE
TRLRH + 2t
RD#
AD15:0
(read)
TRLDV + 2t
TAVDV + 2t
Address Out
Data In
TWLWH + 2t
WR#
TQVWH + 2t
AD15:0
(write)
Address Out
Data Out
† BHE#, INST
Valid
†† BHE#, INST
Valid
Extended Address Out
A19:16
Valid
CSx#
† 80C196NU A-1 Step
†† 80C196NU B Step and 83C196NU
A4391-01
Figure 10. READY Timing, Demultiplexed Bus Mode
32
PRELIMINARY
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
6.2.4.3
8XC196NU Deferred Bus Timing Mode
The deferred bus cycle mode (enabled by setting
CCB1.5) is designed to reduce bus contention when
using the 8XC196NU in demultiplexed mode with
slow memories. When the deferred mode is
enabled, a delay will occur (equal to 2t) in the first
bus cycle following a chip-select change or the first
write cycle following a read cycle. This mode will
work in parallel with wait states. Refer to Figure 11
to determine which control signals are affected.
Cycle 1 is a normal 4t read cycle. Cycle 2 is a write
cycle that follows a read cycle, so a 2t delay is
inserted. Notice that the chip-select change at the
beginning of cycle 2 did not cause a double delay
(4t). The chip-select change in cycle 3, a read cycle,
causes a 2t delay.
CLKOUT
TLHLH + 2t
TWHLH + 2t
ALE
TRHLH + 2t
TAVRL + 2t
RD#
TAVDV,TSLDV + 2t
AD15:0
(read)
Valid
Valid
TAVWL + 2t
WR#
AD15:0
(write)
Data Out
Data Out
Data Out
†BHE#, INST
††BHE#, INST
A19:0
Address Out
Valid
Valid
CSx#
† 80C196NU A-1 Step
†† 80C196NU B Step and 83C196NU
A5097-01
Figure 11. Deferred Bus Mode Timing Diagram
PRELIMINARY
33
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
6.2.5
HOLD#, HLDA# TIMINGS
Table 16. HOLD#, HLDA# Timings
Symbol
Parameter
Min
THVCH
HOLD# Setup Time (To guarantee recognition at next clock)
65
TCLHAL
CLKOUT Low to HLDA# Low
–15
–15
Max
Units
ns
15
ns
TCLBRL
CLKOUT Low to BREQ# Low
THALAZ
HLDA# Low to Address Float
15
ns
33
ns
THALBZ
HLDA# Low to BHE#, INST, RD#, WR# Weakly Driven
25
ns
TCLHAH
CLKOUT Low to HLDA# High
–25
15
ns
TCLBRH
CLKOUT Low to BREQ# High
–25
25
ns
THAHAX
HLDA# High to Address No Longer Float
–20
ns
THAHBV
HLDA# High to BHE#, INST, RD#, WR# Valid
–20
ns
CLKOUT
THVCH
THVCH
Hold Latency
HOLD#
TCLHAL
TCLHAH
HLDA#
TCLBRL
TCLBRH
BREQ#
THALAZ
THAHAX
A19:0, AD15:0
CSx#, BHE#,
INST, RD#, WR#
WRL#, WRH#
THALBZ
THAHBV
Weakly held inactive
TCLLH
ALE
Start of strongly driven ALE
A2460-03
Figure 12. HOLD#, HLDA# Timing Diagram
34
PRELIMINARY
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
6.2.6
AC CHARACTERISTICS — SERIAL PORT, SYNCHRONOUS MODE 0
Table 17. Serial Port Timing — Synchronous Mode 0
Symbol
TXLXL
Parameter
Min
Serial Port Clock period
SP_BAUD ≥ x002H
SP_BAUD = x001H (Note 1)
Units
6t
4t
Serial Port Clock falling edge to rising edge
SP_BAUD ≥ x002H
SP_BAUD = x001H (Note 1)
TXLXH
Max
ns
ns
4t – 27
2t – 27
4t + 27
2t + 27
ns
ns
TQVXH
Output data setup to clock high
4t – 30
ns
TXHQX
Output data hold after clock high
2t – 30
ns
TXHQV
Next output data valid after clock high
TDVXH
Input data setup to clock high
TXHDX
Input data hold after clock high
TXHQZ
Last clock high to output float
2t + 30
ns
2t + 30
ns
0
ns
t + 30
ns
NOTE:
1. The minimum baud-rate (SP_BAUD) register value for receive is x002H and the minimum baud-rate
(SP_BAUD) register value for transmit is x001H.
TXLXL
TXD
TXHQV
TXLXH
RXD
(Out)
0
1
2
Valid
4
3
TDVXH
RXD
(In)
TXHQZ
TXHQX
TQVXH
7
6
5
TXHDX
Valid
Valid
Valid
Valid
Valid
Valid
Valid
A2080-02
Figure 13. Serial Port Waveform — Synchronous Mode 0
PRELIMINARY
35
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
6.2.7
EXTERNAL CLOCK DRIVE
Table 18. External Clock Drive
Symbol
FXTAL1
TXTAL1
Parameter
Min
Max
Units
External Input Frequency (1/TXLXL), PLL disabled
16
50†
MHz
External Input Frequency (1/TXLXL), PLL in 2x mode
8
25
MHz
External Input Frequency (1/TXLXL), PLL in 4x mode
8
12.5
MHz
Oscillator Period (TXLXL), PLL disabled
20
62.5
ns
Oscillator Period (TXLXL), PLL in 2x mode
40
125
ns
80
125
ns
TXHXX
High Time
Oscillator Period (TXLXL), PLL in 4x mode
0.35TXTAL1
0.65TXTAL1
ns
TXLXX
Low Time
0.35TXTAL1
0.65TXTAL1
ns
TXLXH
Rise Time
10
ns
TXHXL
Fall Time
10
ns
†
Assumes an external clock; the maximum input frequency for an external crystal oscillator is 25 MHz.
TXHXX
TXHXL
TXLXH
0.7 VCC + 0.5 V
T
0.7 VCC + 0.5 V
XLXX
0.3 VCC – 0.5 V
0.3 VCC – 0.5 V
T
XLXL
A2119-02
Figure 14. External Clock Drive Waveforms
3.5 V
0.45 V
2.0 V
0.8 V
Test Points
2.0 V
0.8 V
AC testing inputs are driven at 3.5 V for a logic "1" and 0.45 V for
a logic "0". Timing measurements are made at 2.0 V for a logic
"1" and 0.8 V for a logic "0".
A2120-02
Figure 15. AC Testing Output Waveforms During 5.0 Volt Testing
36
PRELIMINARY
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
VLOAD + 0.15 V
VOH – 0.15 V
Timing Reference
Points
VLOAD
VLOAD – 0.15 V
VOL + 0.15 V
For timing purposes, a port pin is no longer floating when a
150 mV change from load voltage occurs and begins to float
when a 150 mV change from the loading VOH/VOL level occurs
with IOL/IOH ≤15 mA.
A2121-01
Figure 16. Float Waveforms During 5.0 Volt Testing
PRELIMINARY
37
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
7.0
THERMAL CHARACTERISTICS
All thermal impedance data is approximate for static
air conditions at 1 watt of power dissipation. Values
will change depending on operating conditions and
the application. The Intel Packaging Handbook
(order number 240800) describes Intel’s thermal
impedance test methodology. The Components
Quality and Reliability Handbook (order number
210997) provides quality and reliability information.
θJA
θJC
100-pin QFP 80C196NU
55°C/W
11°C/W
100-pin SQFP 80C196NU
66°C/W
16.5°C/W
100-pin QFP 83C196NU
55°C/W
11°C/W
8.0
2.
3.
4.
Table 19. Thermal Characteristics
Package Type
1.
8XC196NU ERRATA
The 8XC196NU may contain design defects or
errors known as errata. Characterized errata that
may cause the 8XC196NU’s behavior to deviate
from published specifications are documented in the
8XC196NU Specification Update (272864-001).
Specification updates can be obtained from your
local Intel sales office or from the World Wide Web
(www.intel.com ).
5.
6.
7.
8.
9.
10.
11.
12.
13.
14.
9.0
DATASHEET REVISION HISTORY
15.
This datasheet is valid for devices with a “B” or “C”
designation at the end of the topside tracking
number. Datasheets are changed as new device
information becomes available. Verify with your local
Intel sales office that you have the latest version
before finalizing a design or ordering devices.
16.
17.
18.
19.
This is the -004 version of the datasheet. The
following changes were made in this version:
1.
2.
3.
4.
All references to “ADVANCE INFORMATION”
have been changed to “PRELIMINARY”.
Table note added to Tables 4 and 6.
Table 15, removed note (2) attachment from
TRHDZ.
Table 15, specification change made to the following timings: TAVDV, TSLDV, TCLYX.
This is the -003 version of the datasheet. The
following changes were made in this version:
38
A heading was added for Section 1.0, “Product
Overview,” and the remaining sections were
renumbered.
List of features, the 8XC196NU has four
options (0–3) for programmable wait states for
each chip select, not sixteen (0–15) as previously stated.
The ROM SQFP (SB83C196NU) pinout and
pin assignment tables have been deleted.
Figure 5, package designator in diagram
changed to “S” from “SB” to correctly indicate
the QFP package type.
Table 8, EA# signal description added.
Table 8, signal descriptions for BREQ#,
HLDA#, HOLD#, PLLEN2:1, and RESET#
have been modified.
Table 9, redesigned and footnotes reordered.
Table 10, VIH2 specification added with footnote.
Figure 6, corrected to state PLLEN2:1=01 (not
PLLEN2:1=10).
Tables 12 and 14, B-step timing added for
TWHBX min and TRHBX min.
Table 12, deleted notes 4 and 5, added note 2,
and reordered remaining notes.
Table 13, deleted notes 1, 3, and 6 and reordered remaining notes.
Table 14, deleted notes 4, 5, and 6, added note
2, and reordered remaining notes.
Table 15, deleted notes 1, 3, and 6 and reordered remaining notes.
Tables 13 and 15, the minimum timing for TRXDX
improved from 2 ns to 0 ns.
Figures 7–11, updated to reflect both A- and Bstep timings on the BHE#, INST signal.
Section 5.4.3, the second sentence of the first
paragraph, the word “and” replaced by “or”.
Table 19, thermal characteristics specifications
have been changed and expanded.
The errata list was replaced with a reference to
the specification update document.
The following changes were made in the -002
version of the datasheet:
1.
The input frequency on XTAL1, formerly called
FOSC, is now called FXTAL1. The internal operating frequency and operating period are
denoted by (f) and (t), respectively.
2.
25 MHz is the maximum input frequency when
using an external crystal oscillator; however,
50 MHz can be applied with an external clock
source.
PRELIMINARY
8XC196NU COMMERCIAL CHMOS 16-BIT MICROCONTROLLER
3.
The minimum frequency input with PLL in 4x
mode has changed from 4 MHz to 8MHz.
4.
The AC characteristics tables have been
divided into the following: the timing specifications met by the device, and the timing specifications that must be met by the external
memory system.
5.
Electrical characteristics notes #2 and #3
added to section 3.0.
6.
Maximum IOL and IOH specifications added to
the DC characteristics tables.
7.
AC timings TAVWL and TSLDV added to the AC
characteristics–multiplexed bus mode tables.
8.
Figure 7 added, and figures 8–12 have been
revised.
9.
Thermal characteristics for the 100-pin SQFP
package have been added in section 1.0.
11. Several AC timing specifications have
changed.
10. Specifications for the 83C196NU have been
added.
PRELIMINARY
39